Chloroplastic NAD(P)H Dehydrogenase in Tobacco Leaves Functions in Alleviation of Oxidative Damage Caused by Temperature Stress

Accumulation of H₂O₂ in Leaves under Temperature-Stressed Conditions

3,3-Diaminobenzidine (DAB) reacts with H₂O₂ in the presence of peroxidase and immediately generates brown polymers that are stable in most solutions. With DAB uptake by leaves, H₂O₂ can be localized in vivo and in situ or on a subcellular level (Thordal-Christensen et al., 1997). Brown marks were not detectable in either ΔndhCKJ or wild-type leaves after treatment at 25°C for 3 h (Fig. 1 ). At 42°C, brown traces were usually seen in ΔndhCKJ leaves within 3 h, and a larger brown area appeared the longer the leaves were exposed to high-temperature stress. Very few brown marks emerged within the wild-type leaves. At 4°C, brown traces usually began to emerge in both wild type and ΔndhCKJ after 1 h of treatment, with a more prominent appearance in the ΔndhCKJ leaves. The results indicated that temperature stress causes an accumulation of H₂O₂ in tobacco leaves with defective ndh genes.

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Figure 1.

Effects of heat (42°C) or chilling (4°C) temperature on the accumulation of H₂O₂ in the leaves of wild-type (WT) and ΔndhCKJ tobacco plants. Petioles were steeped in solutions containing 1 mg mL⁻¹ DAB (pH 3.8) at 25°C in the dark for 1 h to take up the stain. Samples were then incubated at 25°C, 42°C, or 4°C, under illumination at 100 μmol photons m⁻² s⁻¹. H₂O₂ accumulation was detected as brown areas after 3 h (A and B) and after 1 h (C) of treatment.

Changes in PSII Photochemical Activity and CO₂ Assimilation in Response to Temperature Stress

F_v/F_m is a chlorophyll (Chl) fluorescence parameter used to evaluate the maximum or potential quantum efficiency of PSII (Genty et al., 1989; Maxwell and Johnson, 2000). F_v/F_m of leaf discs did not significantly decline during incubation at 25°C for 1 or 6 h, with no obvious differences between wild type and ΔndhCKJ (Fig. 2A ). During treatment at 42°C, F_v/F_m decreased to around 0.74, but there was still no noticeable difference between wild type and ΔndhCKJ. At 4°C, F_v/F_m gradually declined in both wild-type and ΔndhCKJ leaf discs, but the decline in ΔndhCKJ was more remarkable (Fig. 2A). The results indicated that there was no difference between the wild type and mutant in their light-harvesting ability during heat treatment, but that of ΔndhCKJ was more sensitive under chilling treatment.

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Figure 2.

Changes of Chl fluorescence parameters during temperature treatment. Leaf discs were floated on the surface of temperature-controlled cyclic water bath with the epidermal side upward, and treated at indicated temperatures (25°C, 42°C, or 4°C) for the indicated time (1 h, 3 h, or 6 h) under illumination of about 100 μmol photons m⁻² s⁻¹. They were dark adapted at the corresponding temperatures for 10 min. Chl fluorescence was then measured at the same temperature using a PAM emitter-detector unit 101 ED as described in “Materials and Methods.” Values for F_v/F_m = (F_m − F₀)/F_m (A) and ΦPSII = (F_m′ − F)/F_m′ (B) are the averages of four independent measurements. Standard errors are indicated by the vertical bars.

ΦPSII represents the effective photochemical efficiency of PSII, which can indirectly reflect linear electron transport (Genty et al., 1989; Maxwell and Johnson, 2000). Figure 2B shows that ΦPSII of ΔndhCKJ was slightly lower than that of wild type even at 25°C. During incubation at 42°C, ΦPSII continuously decreased, and the value declined even faster in ΔndhCKJ. After incubation at 42°C for 6 h, ΦPSII declined by 28.4% in wild type and by 41.0% in ΔndhCKJ. After treatment at 4°C for 1 h, ΦPSII in wild type had declined by 56.2%, and the decline was more notable in ΔndhCKJ (by 68.2%). Nevertheless, the decline in ΦPSII slackened during subsequent treatment, and the difference between wild type and ΔndhCKJ became less evident. The results indicated that the linear electron transport rate gradually slowed during 42°C stress, and the difference between wild type and ΔndhCKJ also progressively increased up to 6 h after treatment. While ΦPSII dropped rapidly at 4°C, the drop was slower in wild type than in ΔndhCKJ within 1 h of chilling stress.

To obtain further confirmation of the differences in linear electron transport linked to CO₂ assimilation, the dynamic changes in nonphotochemical quenching (qN) were compared between wild type and ΔndhCKJ. The decreasing phases of qN during illumination (light recovery) and after illumination (dark relaxation) reflect the activities of CO₂ assimilation and of energy-dependent heat dissipation, respectively (Horton et al., 1994, 1996; Jones et al., 1998; Ivanov and Edwards, 2000; Maxwell and Johnson, 2000; Müller et al., 2001). Figure 3A shows that the light recovery ability of qN was similar in wild type and ΔndhCKJ at 25°C but was higher in wild type at 42°C. After treatment at 42°C for 6 h, qN stayed at an abnormally high level in ΔndhCKJ, but still showed light recovery ability in wild type, indicating that CO₂ assimilation was much less inhibited in wild type than in ΔndhCKJ when suffering heat stress. On the other hand, after treatment at 4°C for 6 h, there was a great increase in qN, and light recovery was seriously inhibited in both wild type and ΔndhCKJ. The dark relaxation of qN was notably slower in ΔndhCKJ than in wild type but was significantly retarded in both strains (Fig. 3B). These results suggest a regulative role of NDH in alleviating the inhibition of photosynthetic electron transport and in the dissipation of the transthylakoid energy gradient.

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Figure 3.

Effects of heat (42°C) and chilling (4°C) treatments on the kinetics of qN. Leaf discs were treated for 6 h and dark adapted as in Figure 2. qN was measured as described in “Materials and Methods.” The AL was turned on at 0 min and off at 15 min, but saturating pulses lasted for another 10 min. qN was calculated as 1 − (F_m′−F₀′)/(F_m−F₀).

The measurement of O₂ evolution using leaf fragments suspended in a solution of bicarbonate more directly reflects the activity of CO₂ assimilation. Figure 4 shows that O₂ evolution was inhibited in both wild type and ΔndhCKJ at 42°C, and that the inhibition was much more significant in ΔndhCKJ than in wild-type fragments after 6 h of treatment. No O₂ evolution was detected at 4°C. These results confirmed that CO₂ assimilation was more strongly inhibited in the NDH-defective mutant at the high temperature and was almost totally inhibited at the low temperature in both strains.

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Figure 4.

Effects of heat (42°C) and chilling (4°C) treatments on photosynthetic oxygen evolution. Leaf discs were treated as in Figure 2, cut into fragments of 1 mm², and stirred in a 1.8-mL suspension (0.11 mg Chl mL⁻¹) containing 0.1 m NaHCO₃ and 0.05 m Tris (pH 7.5) in the thermostated glass vessel of a Clark-type oxygen electrode. O₂ evolution was normally detected several minutes after the start of illumination (800 μmol photons m⁻² s⁻¹) at 25°C or 42°C, but was not detectable at 4°C (indicated with asterisks [*]). Values are the averages of four independent measurements. Standard errors are indicated by the vertical bars. The control rate of O₂ evolution (wild type, 25°C, 1 h) was 67.2 μmol O₂ mg Chl⁻¹ h⁻¹.

Effects of Temperature Stress on PSI-Cyclic Electron Transport Mediated by NDH

A transient postillumination increase in Chl fluorescence is considered to arise from the reduction of PQ by NAD(P)H or other reducing substances that accumulated in the light. This reaction mainly involves PSI-cyclic electron transport mediated by NDH in cyanobacteria (Mi et al., 1995) and in higher plants (Burrows et al., 1998; Kofer et al., 1998; Shikanai et al., 1998). Figure 5 shows that there is a visible transient postillumination increase in Chl fluorescence in wild-type leaves at 25°C, while it was severely impaired in ΔndhCKJ. When the leaves were treated at 42°C, either the initial rate of the increasing phase or the amplitude of the postillumination increase in Chl fluorescence was enhanced in wild type, with only a trace increase in ΔndhCKJ. In contrast, when treated at 4°C, both wild type and ΔndhCKJ showed a decreased level of fluorescence with slower kinetics and no transient peaks after removal of the white actinic light (AL).

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Figure 5.

Effects of heat (42°C) and chilling (4°C) on postillumination increase of Chl fluorescence in the leaves of wild type and ΔndhCKJ. F₀, Dark fluorescence level; and AL, white actinic light (200 μmol photons m⁻² s⁻¹, lasted for 2 min). Insets show transient increase in Chl fluorescence following light-to-dark transition. Leaf discs were dark adapted on a temperature-controlled plate at indicated temperatures for 10 min and then the fluorescence was measured at the same temperature.

The fast kinetics of Chl fluorescence following a pulse light reflects the reduction of PQ (Joët et al., 2002b; Joliot and Joliot, 2002). The rise in fluorescence observed in the first 200-millisecond (ms) time range showed a prominent peak in wild type after treatment at 42°C but only slightly increased in ΔndhCKJ leaves (Fig. 6 ), indicating that PQ could be rapidly reduced and reoxidized in wild-type leaves. However, neither the wild type nor the mutant exhibited reduction of PQ at 4°C. These data further confirm that the reduction of PQ by NDH-dependent cyclic electron flow is augmented by heat but not chilling exposure.

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Figure 6.

Effects of heat (42°C) and chilling (4°C) treatments on the kinetics of fluorescence induction curve. Leaf discs were treated for 6 h and dark adapted as in Figure 2. Chl fluorescence was measured and recorded as described in “Materials and Methods.”

The dark rereduction of P700⁺ is a more direct reflection of the rate of cyclic electron transport around PSI and of the electron donation to the intersystem electron transport chain by stromal reductants (Maxwell and Biggins, 1976; Mi et al., 1992a, 1992b; Havaux, 1996). At 25°C, the initial rate of P700⁺ rereduction after turning off of the far-red light was slower in ΔndhCKJ than in wild type by 14.2% (Fig. 7 ). After 42°C stress, the initial rate was accelerated in both and more notably accelerated in wild type. It was slower in ΔndhCKJ than in wild type by 16.9%. After 4°C treatment, the initial rate measured under this temperature was slowed and was slower in ΔndhCKJ than in wild type by 14.6%. Together, these results reveal that the cyclic electron transport mediated by NDH is enhanced at the high temperature and suppressed at the low temperature.

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Figure 7.

Effects of heat (42°C) and chilling (4°C) on the initial rates (0–1 s) of P700⁺ rereduction following far-red light in wild type and ΔndhCKJ. Leaf discs were treated as in Figure 5. Dark reduction of P700⁺ was measured by turning off of the far-red light (>705 nm, 5.2 μmol photons m⁻² s⁻¹) after a 30-s illumination that allowed the oxidation of P700 to a steady state. Each experiment was repeated four times. Standard errors are indicated by the vertical bars.

The Transthylakoid Proton Gradient and Photophosphorylation

The ms-delayed light emission (ms-DLE) of Chl fluorescence was used to monitor the transthylakoid proton gradient (ΔpH; Wraight and Crofts, 1971; Li and Shen, 1994). The ms-DLE from wild-type leaf discs was higher than that from ΔndhCKJ both before and after temperature treatment (Fig. 8 ), suggesting the involvement of the NDH pathway in the formation of ΔpH. To investigate whether the NDH-dependent transthylakoidal ΔpH contributes to ATP synthesis, light-induced ATP synthesis in intact chloroplasts was analyzed (Fig. 9 ). After illumination of the dark-adapted chloroplasts for 1 min at 25°C, there was ATP synthesis in wild-type chloroplasts but very little in those from the ΔndhCKJ mutant. This finding is indicative of the operation of photophosphorylation through rapidly activated cyclic electron transport mediated by NDH under CO₂ assimilation retarded conditions. ATP synthesis was also observed in both wild type and ΔndhCKJ at 42°C (much more in wild type), while no photophosphorylation occurred at 4°C. The results indicate that cyclic photophosphorylation via NDH functions when CO₂ assimilation was inhibited under heat-stressed conditions.

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Figure 8.

Effects of heat (42°C) and chilling (4°C) treatments on ms-DLE. Leaf discs were treated for 6 h and dark adapted as in Figure 2. The ms-DLE was measured as described in “Materials and Methods.”

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Figure 9.

Light-induced ATP synthesis of chloroplasts. The 1-mL reaction mixture contained 0.4 m Suc, 50 mm Tris-HCl (pH 7.6), 10 mm NaCl, 5 mm MgCl₂, 2 mm ADP, 10 mm Na₂HPO₄, and intact chloroplasts with 30 μg of Chl. After illumination (800 μmol photons m⁻² s⁻¹) for 1 min at 25°C, 42°C, or 4°C, ATP contents of the illuminated and dark-controlled sample were analyzed using the Luciferin-luciferase method. Values are the averages of six independent measurements. Standard errors are indicated by the vertical bars. The control value of ATP contents (100%) was about 31.4 nmol ATP mg Chl⁻¹.

Temperature Stress Induced H₂O₂ Production in ΔndhCKJ Strain

ROS such as superoxide anion radical and H₂O₂ are inevitably photoproduced in chloroplasts (Asada and Kiso, 1973; Asada et al., 1974) and are rapidly scavenged through water-water cycle (Asada, 1999). However, under heat- or chilling-stressed conditions, Calvin cycle enzymes (especially Rubisco activase) are depressed, leading to suppression of CO₂ assimilation (Weis, 1981; Kingston-Smith et al., 1997; Allen and Ort, 2001; Salvucci and Crafts-Brandner, 2004a, 2004b) and overreduction of stromal components. Inhibition of CO₂ assimilation enhances the electron flow to O₂, generating more·superoxide anion radical (Asada, 1992). Compared with the accumulation of H₂O₂ (Fig. 1), decrease in CO₂ assimilation (Fig. 4) occurred much earlier during temperature stress. Thus, accumulation of H₂O₂ in the leaves of ΔndhCKJ (under either heat or chilling stress) and wild-type (under chilling stress) leaves (Fig. 1) should be the result of the inhibition of linear electron transport (Fig. 2B). It has been suggested that NDH and PQ are involved in the chlororespiratory process that consumes ROS, and that they might poise the reduced and oxidized forms of the intermediates of cyclic electron transport with a constructed in vitro system (Casano et al., 2000). However, there was no direct evidence for involvement of the NDH pathway in ROS scavenging. This work provides direct evidence for the involvement of the NDH-dependent pathway in the suppression of ROS generation in chloroplasts.

CO₂ Assimilation Was Greatly Inhibited in the ΔndhCKJ Mutant

At the high temperature, the light energy harvested and transferred by PSII was not obviously reduced, and it maintained a similar level between wild type and ΔndhCKJ (Fig. 2A). Nevertheless, linear electron transport (Fig. 2B), as well as CO₂ assimilation (Fig. 4), was increasingly limited. The ΔndhCKJ mutant exhibited a more severe inhibition, especially after 6 h of stress treatment (Figs. 2B, 3, and 4). These results implied that the NDH pathway was involved in regulation of CO₂ assimilation, thus reducing the generation of ROS under heat stress. Differently, chilling stress induced a continuous decrease of F_v/F_m and a large drop in ΦPSII (Fig. 2), indicating that the light energy harvested and transferred by PSII was reduced, leading to a slowdown of apparent electron transport. As a result, the protective role of the NDH pathway became less important (Fig. 1).

A typical qN induction curve measured under optimal physiological conditions is composed of an initial rise to a high level, which reflects the rapid buildup of ΔpH, and the gradual decrease to a steady-state level in the course of activation of the Calvin cycle, consuming ATP and thus relaxing ΔpH (Jones et al., 1998). After 6 h of heat stress, the qN induction curve in the ΔndhCKJ mutant lost the decreasing phase and stayed at a high level, while wild type retained the typical induction curve due to less inhibition of CO₂ assimilation (Fig. 3A). Under chilling stress, qN induction curves achieved even higher levels in both strains, while the dark relaxation of qN was more retarded in ΔndhCKJ than in wild type (Fig. 3B). The results further supported the regulative role of NDH in alleviating the inhibition of CO₂ assimilation and also its possible involvement in the transthylakoid energy gradient. The much more significant inhibition of photosynthetic O₂ evolution in ΔndhCKJ than in wild type after 6-h heat treatment (Fig. 4) again strengthened our suggestions.

PSI-Cyclic Electron Transport Mediated by NDH Functions in Acclimating to Temperature-Stressed Conditions

Previous work has shown that wild-type, but not Ndh-deficient tobaccos, exhibited a postillumination increase in fluorescence after photooxidative treatment that paralleled with higher Ndh complex level, activity, and an increase in thylakoid peroxidase (Martín et al., 2004). Consistent with this result, enhancement of the postillumination increase in Chl fluorescence and the more notable acceleration of P700⁺ rereduction in wild type under heat stress (Figs. 5 and 7) indicated that the NDH-dependent cyclic pathway was stimulated under oxidative conditions caused by heat stress. Similarly, the fast kinetics of Chl fluorescence indicated that PQ could be rapidly reduced and reoxidized in wild type under heat treatment (Fig. 6), further demonstrating the effective activation of the NDH-related pathway in response to heat stress.

To prevent overreduction of stromal components and formation of ROS, excess electrons must be efficiently consumed, either by the Calvin cycle or by other electron valves. When CO₂ assimilation was inhibited under heat stress (Fig. 4), alternative electron valves such as Mehler reaction and photorespiration as well as cyclic electron flow (Figs. 5 and 7), might become evident. Since plastid terminal oxidase (PTOX) is able to transfer electrons from PQ to oxygen without generating ROS (Cournac et al., 2000; Josse et al., 2003), NDH and PTOX involved in chlororespiration were suggested to function to provide and remove electrons, respectively, thus to balance the redox state of transporters (Niyogi, 2000; Martín et al., 2004; Streb et al., 2005). Changes in the redox state of intersystem electron carriers by chlororespiration have been indicated to tightly control the rate of PSI-driven cyclic electron flow in vivo (Joët et al., 2002a). Since the potential electron consumption by chlororespiration is currently thought to be very low (Ort and Baker, 2002) and the content of PTOX is low in many plant species (Streb et al., 2005), its function remains to be clarified under the stressed conditions.

Coincident with a previous report (Savitch et al., 2001), in contrast to heat, chilling stress inhibited the cyclic electron flow (Figs. 5, 6, and 7). This inhibition might be the result of the slowing down of the apparent electron transport (Fig. 2) and inactivation of enzymes involved in the operation of photosynthesis, including NDH. Nevertheless, some studies have shown that PSI-cyclic electron transport is accelerated by chilling stress (Kim et al., 2001; Barth and Krause, 2002; Bukhov et al., 2004). The discrepancy may be attributed to different measurement conditions. The former were carried out at chilling temperature while the latter were at room temperature, which might reflect the recovery process. Actually, we found that the complete inhibition of photosynthetic O₂ evolution could be completely recovered once shifted to 25°C (data not shown). The accumulation of H₂O₂ in wild-type leaves at the low temperature (Fig. 1) might be attributed to the suppression of NDH-dependent cyclic electron flow. Thus, the role of NDH in photoprotection at low temperature is less important compared with that at high temperature.

The NDH Pathway Probably Provides Extra ATP for Regulation of CO₂ Assimilation

It has been proposed that NDH-dependent cyclic electron transport plays a role in supplying extra ATP for optimal photosynthesis, particularly under conditions when CO₂ is limiting (Peltier and Cournac, 2002). However, there was no direct proof of supplementation of extra ATP by NDH-mediated cyclic electron transport. On the basis of the slower rising phase of the nonphotochemical qN induction curve in the NDH-defective mutant under water-stressed conditions, it has been suggested that PSI-cyclic electron transport mediated by NDH was responsible for enhanced proton pumping and was involved in energy dissipation when CO₂ availability reduced (Burrows et al., 1998). In this work, the higher ms-DLE in wild type than in ΔndhCKJ (Fig. 8) denoted the formation of ΔpH through NDH-mediated cyclic electron transport under either stressed or nonstressed conditions. A 9-aminoacridine fluorescence quenching analysis showed a similar trend (data not shown). Moreover, when CO₂ assimilation did not operate in the intact chloroplasts in the absence of acceptor at either 25°C or 42°C, light-dependent ATP synthesis via NDH pathway occurred (Fig. 9).

One of the roles of transthylakoid ΔpH is to function in photoprotection, necessary for the thermal dissipation of excess absorbed light energy (Niyogi, 1999). Li et al. (2004) suggested that NDH might function by providing extra protons, thus to promote the xanthophylls cycle and mitigate the stromal overreduction. In addition to the xanthophylls cycle (Demming-Adams, 1990), Mehler reaction (Schreiber and Neubauer, 1990; Osmond and Grace, 1995) was suggested to function in radiationless energy dissipation, and water-water cycle would be enhanced by limitation of photosynthesis (Miyake and Yokota, 2000). However, Mehler reaction alone is not sufficient for effective energy dissipation (Clarke and Johnson, 2001). There are reports that strong light also promotes radiationless energy dissipation in npq1-2 mutant, which cannot synthesize zeaxanthin (Niyogi et al., 1998), as in zeaxanthin-containing leaves (Bukhov et al., 2001). Based on this evidence, Heber et al. (2001) suggested that the combination of zeaxanthin and a low intrathylakoid pH were sufficient in some hydrated mosses and green lichens, but not in higher plants, to dissipate energy even when PSII reaction centers are open. Therefore, cyclic electron transport might be responsible for producing the extra thylakoid acidification that leads to the effective dissipation of excess excitant energy as heat. The observed involvement of NDH in protection of the tobacco plant from photooxidative damage (Fig. 1) under temperature-stressed conditions also supports this view.

On the other hand, CO₂ assimilation is usually limited by its key enzyme, Rubisco, which is activated by its molecular chaperone, Rubisco activase, through an ATP-dependent reaction. A series of studies have indicated that the operation of Rubisco activase is sensitive to high and low temperature (Kingston-Smith et al., 1997; Salvucci and Crafts-Brandner, 2004a, 2004b). It is plausible that the suppression of linear electron transport (Fig. 2B) and photosynthetic O₂ evolution (Fig. 4) under heat-stressed conditions might be the result of inhibition of Rubisco activation. The lower level of suppression in wild type might be attributed to the function of NDH-dependent PSI-cyclic electron transport (Figs. 5, 6, and 7). Cyclic photophosphorylation via the NDH pathway (Figs. 8 and 9) might provide extra ATP for activation and stabilization of Rubisco activase under heat stress. It has been suggested that Rubisco activase was activated only by electron transport through PSI, and not by that from PSII (Campbell and Ogren, 1990). Whether the cyclic electron transport mediated by NDH can activate or stabilize Rubisco activase is worth further study. These results suggest that photophosphorylation via NDH pathway might optimize CO₂ assimilation under heat stress, leading to a reduction in the generation of ROS, which would inactivate CO₂ assimilation enzymes (Ishida et al., 1998, 1999) and scavenging enzymes such as ascorbate peroxidases (Mano et al., 2001), thus cause further oxidative damage in leaves.

In conclusion, this work indicates that when the Calvin cycle is inhibited under temperature-stressed conditions, especially under heat stress, PSI-cyclic electron transport mediated by NDH might play an important role in optimization of the photosynthetic apparatus. This function is probably carried out by providing extra ΔpH and ATP to regulate CO₂ assimilation, and poising the redox level of electron transporters through chlororespiration, thus reducing the generation of ROS.

Tobacco Strains, Growth Conditions, and Treatment

Homoplasmic ΔndhCKJ tobacco (Nicotiana tabacum cv Xanthi) mutants in which the chloroplastic ndhC, ndhK, and ndhJ genes were inactivated (Takabayashi et al., 2002) were cultivated along with wild-type plants in a phytotron (about 200–300 μmol photons m⁻² s⁻¹, 12-h light at 25°C and 12-h dark at 20°C). Four- to 6-week-old plants were used for experiments. To perform heat and chilling treatments, leaf discs were floated on the surface of a temperature-controlled cyclic water bath of 25°C, 42°C, or 4°C, with the epidermal side turned up and an illumination of about 100 μmol photons m⁻² s⁻¹.

Detection of H₂O₂ in the Leaves

Young leaves of similar size were cut from 4-week-old plants. The leafstalks were immediately dipped into water containing 1 mg mL⁻¹ DAB (pH = 3.8; Thordal-Christensen et al., 1997) and kept at 25°C in the dark for 1 h to take up the stain. The samples were then placed in illuminating incubators at 25°C, 42°C, or 4°C (about 100 μmol photons m⁻² s⁻¹) for the indicated time, keeping the petioles immersed in the DAB solutions. The Chl was bleached by boiling the leaves in 95% ethanol before taking pictures.

Chloroplast Preparation

Intact chloroplasts were isolated at 4°C according to a modification of the method described by Mills and Joy (1980). Dark-adapted leaves were homogenized in cold medium containing 0.4 m Suc, 50 mm Tris-HCl (pH 7.6), 10 mm NaCl, 2 mm MgCl₂, and 2 mm EDTA. After filtration through two layers of nylon cloth and centrifugation (1,000g for 3 min at 4°C), the pellet was resuspended in the medium and layered onto a 40% and 60% Percoll step gradient. Intact chloroplasts were recovered from the 40%/60% Percoll interface after centrifugation at 3,500g for 10 min at 4°C. After washing, the chloroplasts were pelleted at 2,000g for 3 min at 4°C, suspended in the homogenization medium, and stored on ice in the dark. The intactness of the Percoll-purified chloroplasts from both wild type and ΔndhCKJ was above 90%, which was estimated by ferricyanide-dependent O₂ evolution before and after osmotic shock (Heber and Santarius, 1970).

ATP Synthesis Measurements

Light-induced ATP synthesis of chloroplasts was measured by comparing the ATP level in the dark and 1 min after illumination. One-milliliter reaction mixture contained 0.4 m Suc, 50 mm Tris-HCl (pH 7.6), 10 mm NaCl, 5 mm MgCl₂, 2 mm ADP, 10 mm Na₂HPO₄, and intact chloroplasts with 30 μg of Chl. After illumination (800 μmol photons m⁻² s⁻¹) for 1 min at 25°C, 42°C, or 4°C, 10% TCA was immediately added to the illuminated and dark-controlled samples and neutralized with 3 m Na₂CO₃. ATP content was then analyzed by the Luciferin-luciferase method using a luminometer (RS 9901 luminometer) and ATP bioluminescence assay kit (Shanghai Institute of Plant Physiology, Chinese Academy of Sciences).

Measurements and Analysis of Chl Fluorescence Parameters and the Redox Change of P700

Chl fluorescence was measured according to Schreiber et al. (1986, 1988) using a pulse-amplitude modulated fluorimeter (PAM 101, Walz). After treatment, the leaf discs were dark adapted at the indicated temperatures and the measurement was carried out at the same temperatures. The modulated nonactinic measuring beam (1.6 kHz) was switched on to obtain the initial fluorescence (F₀). Maximal fluorescence (F_m) was measured by illumination with a 0.8-s pulse of white saturating light. Maximum quantum efficiency of PSII was determined by F_v/F_m. The kinetics of the fluorescence induction curve was recorded with a PDA-100 data acquisition system. Using a previously described method with slight modifications (Shikanai et al., 1998), a transient postillumination increase in Chl fluorescence was recorded after termination of the 2-min illumination by AL (200 μmol photons m⁻² s⁻¹). qN was calculated as 1 − (F_m′−F₀′)/(F_m−F₀) based on the F_m′ measured every 30 s with saturating pulses, from turning on the AL until steady-state photosynthesis was reached (15 min of induction). ΦPSII, the photochemical efficiency of PSII, was also calculated at steady state as (F_m′ − F)/F_m′. The redox change of P700 was monitored by absorbance at 810 − 830 nm, using an ED-P700DW-E unit of the PAM fluorometer, and the initial rate of P700⁺ rereduction following far-red light (>705 nm, 5.2 μmol m⁻² s⁻¹) was calculated (Klughammer and Schreiber, 1998).

Photosynthetic Oxygen Evolution Measurements on Leaf Fragments

After the leaf discs were treated at the indicated temperatures for the indicated time, they were cut into fragments of 1 mm² and stirred into a 1.8-mL suspension (0.11 mg Chl mL⁻¹) containing 0.1 m NaHCO₃ and 0.05 m Tris (pH 7.5), in the thermostated glass vessel of a Clark-type oxygen electrode. The leaf discs were vacuum infiltrated with 0.1 m NaHCO₃ after temperature treatment, and the suspension medium was stabilized to the corresponding temperatures for the measurement. O₂ evolution was normally detected several minutes after the beginning of the illumination (800 μmol photons m⁻² s⁻¹).

Measurements of ms-DLE

Measurements of ms-DLE were carried out using a phosphoroscope according to Wang et al. (2003) with modifications. The sample was irradiated with light passing through holes arranged on two rotating wheels, so that the measuring process might be divided into consecutive cycles of 1-ms excitation by light followed by 4.6 ms darkness. The DLE between 2.8 and 3.8 ms after every flash was measured with a photomultiplier, and the signal was recorded continuously by a computer through an analog-digital converter. The leaf discs were treated and dark adapted at the same temperature and were immediately inserted into the sample cell to measure ms-DLE.